KR910005253B1 - Low-frequency converter for carrier chrominance signal - Google Patents

Abstract

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Description

Frequency Low Frequency Converter of Carrier Color Signal

1 is a block diagram showing an embodiment of an apparatus for converting a frequency low frequency signal of a carrier color signal according to the present invention.

2 is a block diagram showing another embodiment.

3 is a block diagram showing a conventional low frequency conversion device of a carrier color signal.

* Explanation of symbols for main parts of the drawings

3: burst gate 16: multiplier

17: extraction circuit 19: first PLL circuit

22: first divider 23: second PLL circuit

29: second dispenser

The present invention relates to an apparatus for frequency converting a carrier color signal to a low range in recording a color image signal on a magnetic tape or the like.

3 is a block diagram showing a conventional low frequency conversion device for a carrier color signal used in a videotape recorder. In the drawing, a carrier color signal having a color carrier frequency f _sc is input to the input unit 1, and a signal synchronized with the horizontal synchronizing signal having a horizontal synchronization frequency f _H is input to the input unit 2, for example, one-shot multi. A signal obtained by triggering the vibrator with the horizontal synchronizing signal is input. The carrier color signal is applied to the burst gate 3, and the burst gate 3 is individualized only in the burst chroma signal period, thereby extracting the burst chroma signal from the carrier color signal and giving it to the multiplier 5 of the PLL circuit 4. do. The multiplier 5 detects the phase by combining the applied burst chroma signal with the output signal of the voltage controlled oscillator 6 (hereinafter referred to as VCO), and only the reduced component of the phase detection output is referred to as a low pass filter (hereinafter referred to as LPF). Through (7) is given to the control input of the VCO (6). For this reason, the output signal of the VCO 6 is stabilized in the phase of the frequency _{fsc which} is the same as the burst chroma signal. This PLL circuit 4 is called a loop APC (Automatic Phase Comtrol) loop.

On the other hand, a signal synchronized with the horizontal synchronizing signal at the input terminal 2 is provided to the multiplier 9 of the PLL circuit 8. The multiplier 9 phase-detects the signal synchronized with the horizontal synchronous signal with the signal obtained by dividing the output of the VCO 10 with the divider 11, and only the low frequency component of the phase detection output is passed through the LPF 12. To the control input of the VCO 10. When the carrier color signal is NTSC and the videotape echo recorder is VHS, the division ratio of the divider 11 is set to, for example, one third. In this case, the output signal of the VCO 10 is in phase with the horizontal synchronization signal and stabilized at a frequency of 320 f _H. The loop of this PLL circuit 8 is called an AFC (Automatic Frequencrol) loop. The output signal of the VCO 10 is divided into the divider 13. The frequency division ratio of the frequency divider 13 is selected, for example, by one eighth, whereby a signal having a frequency of 4 f _H is obtained at its output. The frequency divider 13 serves as a phase shift switching circuit in the VHS system, and rotates the phase of the output signal by 90 degrees every one horizontal synchronization period, and reverses the rotation direction of the phase for each field. This is a process for preventing crosstalk in adjacent tracks and is generally named PS (Phase Shift). Furthermore, in the case of the exclusive method, P1 (Phase Inver) processing is performed. The output signals of the VCO 6 and the divider 13 are input to a multiplier 14 called a bus, a balanced modulator. Multiplier 14 has frequencies f _sc and 40 f _H, respectively. Multiply these two signals and output a signal containing two frequency components of f _sc ± 40f _H. Double f _sc ± only the frequency component of the 40f _H is a (hereinafter referred to as BPF) band-pass filter to the take-off (15) is input to the multiplier 16, which is referred to as a main balanced modulator.

The carrier color signal applied to the input terminal 1 is also input to the one multiplier 16. Multiplier 16 multiplies two input signals with frequencies f _sc and f _sc ± 40f _H , respectively, and outputs a signal containing two frequency components of f _sc ± (f _sc ± 40f _H ). Of these, only signals of the frequency component of 40 f _H are extracted to the extraction circuit 17 made of, for example, LPF.

The signal thus obtained is a low inverse color signal in the VHS system. This low-conversion color signal is signal-processed by an unillustrated burst emulation circuit recording killer circuit and recording amplifier and then polymerized with the luminance signal and supplied to the recording head 18 of the video tape recorder. For example, when jitter is included in the broadcast color signal applied to the input terminal 1 during dubbing, this jitter is a signal synchronized with the burst chroma signal output from the burst gate 3 or the horizontal synchronization signal applied to the input terminal 2. Since the jitter of the carrier color signal is canceled by the multiplier 16 by the jitter of the output signal of the BPF 15.

The conventional low frequency converter of the carrier color signal has the following drawbacks because it is configured as described above.

(Iii) Due to the complex configuration, the number of parts is large and the circuit size is large.

(Ii) The output of the multiplier 14, which is a subbalanced modulator, generates a lot of spurious, the main of which is output as a result of multiplying the signal synchronized with the horizontal synchronizing signal by the PLL circuit 8 and dividing it by the divider 13. the summation of the output signals of the spurious component and a VCO (6) of the signal in the frequency 40f _H, a frequency component of the difference. Since this cannot be sufficiently removed by the BPF 15, unnecessary components are generated at the output of the multiplier 16, which causes noise.

The present invention has been made in order to solve the above problems, and the tracking of the jitter of the input color signal is achieved in the same way as the conventional device, while obtaining a low frequency conversion device for the color signal of the carrier color signal having a small circuit size and no unnecessary spurious. For the purpose of

A frequency low-frequency conversion device of a carrier color signal according to the present invention includes a first PLL circuit for outputting a first continuous wave signal having a frequency of an integer multiple of the frequency of the extracted burst chroma signal and a means for extracting a burst chroma signal from the carrier color signal. And a first divider for dividing the first continuous wave signal, the frequency divider of the first continuous wave signal to have a frequency of summing or difference between the frequency of the carrier color signal and the frequency of the low-conversion color signal. And a frequency converting means for outputting two continuous wave signals, a multiplier for multiplying the carrier color signal with the second continuous wave signal, and means for extracting the low-conversion color signal from the output signal of the multiplier.

In the present invention, the multiplier receives the signal generated by the first PLL circuit and the frequency converting means and the carrier color signal and generates a low-conversion color signal. Therefore, the multiplier filters the multiplier as a sub-balanced modulator and its output signal in the conventional apparatus. The BPF becomes unnecessary.

1 is a block diagram showing an embodiment of an apparatus for converting a frequency low frequency signal of a carrier color signal according to the present invention.

In the figure, the carrier color signal applied to the input terminal 1 is input to the burst gate 3. The burst gate 3 has only a burst chroma signal period, whereby a burst chroma signal is extracted from the carrier color signal and applied to the multiplier 20 of the first PLL circuit 19. The multiplier 20 multiplies the given burst chroma signal with the output signal of the VCO 21 to detect the phase, and only the low pass component of the phase detection output is applied to the control input of the VCO 21 through the LPF 22. For this reason, the output signal of the VCO 21 is stabilized with the phase of the frequency _{fsc which} is the same as the burst chroma signal. That is, a burst chroma signal of continuous waves is obtained.

The output signal of the VCO 21 is divided by the first divider 22. Now, if the division ratio of the first divider 22 is set to 91/91, the NTSC method has a ratio between the color carrier frequency f _sc and the horizontal synchronization frequency f _H.

f _sc = (455/2) f _H. … … … … … … … … … … … … … … … … … … … (One)

Since the frequency of the output signal of the first divider 22 is

(455/2) f _H x (1/91) = (5/2) f _H. … … … … … … … … … … … … (2)

Becomes

The output signal of the first divider 22 is provided to the multiplier 24 of the second PLL circuit 23. The multiplier 24 multiplies the output signal of the first divider 22 by the signal obtained by dividing the output of the VCO 25 into the divider 26 and phase detects only the low frequency component of the phase detector output. 27 to the control input of the VCO 25.

Now, if the division ratio of the divider 26 is set to 1/107, the frequency of the output signal of the VCO 25 is

(5/2) f _H x 107 = (535/2) f _H ... … … … … … … … … … … … … … … (3)

Becomes In addition, since the second PLL circuit 23 is phase locked to the output signal of the first divider 22, the phase of the output signal of the VCO 25 becomes the same as that of the burst chroma signal. Here, using the relationship in (1)

(535/2)) f _H = (455/2) f _H + 40f _H = f _sc + 40f _{H... … … … … … … …} (4)

Is transformed into

The multiplier 16, which is the main balanced modulator, is input with a carrier color signal applied to the input stage 1 and an output signal of the VCO 25. Multiplier 16 multiplies two input signals with frequencies f _sc and f _sc + 40f _H , respectively, and outputs a signal containing two frequency components of f _sc ± (f _sc ± 40f _C ). Of these, only signals of the frequency component of 40 f _H are extracted by the extraction circuit 17, and a low conversion color signal in the VHS system is obtained. LPF is generally used as the extraction circuit 17. This low-pass color signal uses LPF, not shown. This low-conversion color signal is signal-processed by an unillustrated burst-emphasis circuit recording killer circuit and recording amplifier circuit and then polymerized with the luminance signal and supplied to the recording head 18 of the video tape recorder. For example, when jitter is included in the carrier color signal applied to the input terminal 1 at the time of dubbing, this jitter is also included in the burst chroma signal drawn out from the burst gate 3. For this reason, since the VCO 21 of the first PLL circuit 19 follows it and the VCO 25 of the second PLL circuit 23 follows it, the multiplier 16 whose main balance is also a modulator as in the prior art. Jitter is canceled at.

According to the embodiment, there are many advantages as follows.

(Iii) In the conventional apparatus of FIG. 3, the multiplier 14 and the BPF 15, which are sub-balanced modulators, can be omitted, the configuration is simple, and the number of parts can be reduced, resulting in a relatively small circuit size.

(Ii) There is little unnecessary spurious in the output signal of the VCO 25. For example, since it is a relatively high frequency component that is an integer multiple of the frequency (535/2) f _H of the output signal, the influence is sufficiently eliminated in the extraction circuit 17 made of, for example, LPF. Therefore, the S / N of the low frequency conversion color signal is good.

(Iii) It is not necessary to create and input a signal synchronized with the horizontal synchronous signal as in the conventional apparatus. For this reason, a circuit structure becomes simple similarly to the above. Moreover, since there is no spurious low frequency that is generated in the signal processing system, and it is not affected by horizontal sync signal condensation, it is possible to obtain a stable and high precision low conversion color signal.

(Iii) Since the frequency of the output signal of the first divider 22 is set to (5/2) f _H , this frequency component leaks into the LPF 27 of the second PLL circuit 23. Even if the output frequency of the VCO 25 is phase-modulated at (5/2) f _H , the influence on the screen during playback is frequency-interleaved, making it difficult to visually identify. Furthermore, the same effect is obtained when the frequency of the output signal of the first divider 22 is an odd multiple of 2/1 of the horizontal synchronization frequency f _H.

2 is a block diagram showing another embodiment of the frequency low-frequency conversion device of the carrier color signal according to the present invention. In this embodiment, a divider 28 having a dividing ratio of 1 / m is provided in the first PLL circuit 19 phase locked to the burst chroma signal, and the output of the VOC 21 is divided by the divider 28. By inputting one signal to the multiplier 20, a continuous wave signal whose frequency is m times that of the burst chroma signal is obtained. This continuous wave signal is divided by the first divider 22, multiplied by the second PLL circuit 23, and then divided by the second divider 29 provided at the blocking of the second PLL circuit 23. And is given to the multiplier 16. For example, since the multiplication ratio by the first PLL circuit 19 is canceled by the division ratio of the second divider, the division ratio of the second divider 29 is canceled. If the ratio and the multiplication ratio of the second PLL circuit 23 are the same as, for example, the above embodiment, the frequency of the output signal of the second divider is (535/2) f _H. In general, the multiplication ratios of the first and second PLL circuits 19 and 23 and the division ratios of the first and second dividers 22 and 29 are determined by the second divider 29. When the frequency of the output signal is suitably selected to be (535/2) f _H. Also, the second PLL circuit 23 and the second divider 29 are removed and the frequency is in phase with the burst chroma signal only by the first PLL circuit 19 and the first divider 22. (535/2) f _H can generate and generate a continuous wave signal. In this case, for example, the multiplying ratio of the first PLL circuit 19 is 107 times between the first divider 23 and the multiplier 1 in the embodiment of FIG. 2 in the second divider 29 and the multiplier. What is necessary is just to set between (16), respectively. In the embodiment of FIG. 2, the second divider 29 may serve as a phase shift circuit.

Moreover, in the above embodiment, the case where the NTSC type color video signal is recorded by the VHS type video tape recorder has been described, but it can be applied to the other type color video signal or the video tape recorder. A signal having a sum of the frequency of the broadcast color signal and the frequency of the low-conversion color signal is input to the multiplier 16, which is the main balance modulator, together with the carrier color signal, but may be a signal having a difference frequency.

As described above, according to the present invention, a sum or difference between the frequency of the carrier color signal and the frequency of the low-conversion color signal by a frequency converting means including at least a first divider for the first continuous wave signal phase locked to the burst chroma signal. Since a second continuous wave signal having a frequency of 2 is converted into a main balanced modulator to be input together with a carrier color signal, the jitter of the carrier color signal is achieved in the same way as a conventional device, while the circuit size is small and unnecessary spurious is generated. There is an effect that a frequency low-pass converter of a carrier color signal that is not provided is obtained.

Claims (5)

Apparatus for obtaining a low-conversion color signal by frequency-converting a carrier color signal to a low frequency band, comprising: means for extracting a burst chroma signal from the carrier color signal (3), and phase-locked to the extracted burst chroma signal to determine a frequency of the burst chroma signal; At least a first PLL circuit 19 for outputting a first continuous wave signal having an integer multiple of the frequency and a first divider 22 for dividing the first continuous wave signal, and receiving the first continuous wave signal. A frequency converting means (23) for frequency conversion to output a second continuous wave signal having a frequency for outputting a second continuous wave signal having a sum of the frequency of the carrier color signal and the frequency of the low-conversion color signal or a difference frequency; ) And the number of outputting the low-conversion color signal from the output signal of the multiplier 24 and the multiplier of the carrier color signal and the second continuous wave signal. 27 and a low frequency converted color signal transfer device having a. 2. The carrier according to claim 1, wherein said frequency converting means (23) again includes a second PLL circuit (23) which is phase locked to the output signal of said first divider (22) to multiply and output said output signal. Frequency low frequency converter of color signal. 3. The apparatus of claim 2, wherein said frequency converting means further comprises a second divider (29) for dividing an output signal of said second PLL circuit (23). 3. The method of claim 2, wherein the carrier color signal is NTSC, and the first continuous wave signal output from the first PLL circuit 19 has the same frequency as the burst chroma signal and the first divider ( 22) the frequency division ratio of the carrier color signal of 1/91 and the multiplication ratio of the second PLL circuit (23) is 107 times. 3. The apparatus of claim 2, wherein the frequency of the output signal of the first divider (22) is selected at an odd multiple of 1/2 the horizontal synchronization frequency.

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